Constant on-time (cot) control in isolated converter

ABSTRACT

A constant on-time isolated converter comprises a transformer with a primary side and a secondary side. The primary side is connected to an electronic switch and secondary-side is connected to a load and a processor. The processor is connected to a driver on primary side through at least one coupling element and to the electronic switch. The processor receives an output voltage or an output current across the load generating a control signal accordingly. The driver receives the control signal through the coupling element and accordingly changes the ON/OFF state of the electronic switch, regulating the output voltage and the output current via the transformer, where the duration of the ON/OFF state of the electronic switch is determined between the moment control signal changes from negative to positive and the moment it changes from positive to negative to achieve a high-speed load transient response.

CROSS-REFERENCE TO RELATED APPLICATIONS

This patent application is a Continuation Application of a pendingpatent application Ser. No. 14/562,727 filed to USPTO on Dec. 7, 2014.The pending patent application Ser. No. 14/562,727 claims the prioritybenefit of Taiwanese patent application number 103131589 filed on Sep.12, 2014. The entire disclosure made in the patent application Ser. No.14/562,727 and the entire disclosure made in the Taiwanese patentapplication number 103131589 are hereby incorporated by reference.

FIELD OF THE INVENTION

The present invention relates to an isolated converter, and moreparticularly relates to an isolated converter implementing constanton-time control to regulate output voltage.

BACKGROUND OF THE INVENTION

With recent advances in technology, electronic products have beendeveloped to meet the diverse needs in everyday life. As these productsare made of various electronic components with different power supplyand voltage requirements, the AC power supply from wall needs to beconverted to appropriate voltages for each of the electronic componentsto ensure proper operation.

Conventional AC/DC Converters implement an isolated voltage dividerdesign. After coupling the AC power with rectifiers, a transformer isused to convert the high voltage AC power to low voltage DC power thatcan be used by the devices. As shown in FIG. 1, the conventional powerconverter includes a transformer 10, which includes a primary sideconnected to an electronic switch 12 and a secondary side connected to aload 14, an output capacitor 15 and a voltage divider 16 connected to aprocessor 18. Through a photo-coupler 20, the processor 18 is connectedto a controller 22 that is connected to electronic switch 12 to controlits switching state. When a voltage is applied across load 14, thevoltage divider 16 retrieves a feedback voltage from the load and sendsit to the processor 18 that generates an analog signal accordingly andthen transmits it from the secondary side through the photo-coupler 20to the controller 22 in the primary side. Controller 22 changes theON/OFF state of electronic switch 12 according to this analog signal.Since the processor 18 comprises of TL431 (three-terminal programmableshunt regulator) and VM (voltage-mode) compensation circuit, it useszero/pole compensation to compensate the loop gain and bandwidth toreduce the ripple signal of the load voltage, stabilizing the wholesystem. However, the controller 22 is located on the primary side andthus cannot detect the load voltage directly. There is also delay inTL431 and the VM compensation circuit transmitting the signal generatedfrom the feedback voltage of the load to the controller 22, resulting inthe load voltage not being stabilized quickly. Furthermore, it isdifficult to be controlled in a continuous current mode (CCM) whenhaving a synchronous rectifier in the secondary side.

SUMMARY OF THE INVENTION

A constant on-time (COT) isolated converter is connected to an inputterminal for receiving an input voltage. The COT isolated convertercomprises a transformer, a processor, a driver, and a first electronicswitch.

The transformer comprises a primary side and a secondary side. Theprimary side is connected to the input terminal. The secondary side isconnected to a load. The processor receives an output voltage or anoutput current applied onto the load to generate a control signal. Aduration for the ON/OFF state of the first electronic switch isdetermined by an instance the control signal changes from negative topositive and an instance the control signal changes from positive tonegative.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a circuit diagram of a conventional isolated converter.

FIG. 2 is a circuit diagram of an isolated converter according to afirst embodiment of the present invention.

FIG. 3A shows the waveform of the feedback voltage DV or the detectionvoltage DS and the control signal.

FIG. 3B shows the waveform of the feedback voltage DV or the detectionvoltage DS and another control signal.

FIG. 4 is a circuit diagram of an isolated converter according to asecond embodiment of the present invention.

FIG. 5 is a circuit diagram of an isolated converter according to athird embodiment of the present invention.

FIG. 6 is a circuit diagram of an isolated converter according to afourth embodiment of the present invention.

FIG. 7 is a circuit diagram of an electrical signal extractor, includinga voltage divider, connecting to the controller, the output capacitor,the load and the transformer.

FIG. 8 is a circuit diagram of an alternative electrical signalextractor, including a resistor, connecting to the controller, theoutput capacitor, the load and the transformer.

FIG. 9 is a circuit diagram showing the current flow between thecontroller and the driver.

FIG. 10 shows the waveforms of the feedback voltage DV, the seconddigital signal D1, and RX and TX signals.

FIG. 11 is a schematic diagram of the package structure of thecontroller, the capacitor and the driver.

FIG. 12 is a circuit diagram of an isolated converter according to afifth embodiment of the present invention.

FIG. 13 shows the waveforms of D, M, DI and DS signals of the fifthembodiment of the present invention.

FIG. 14 is a circuit diagram of an isolated converter according to asixth embodiment of the present invention.

FIG. 15 is a circuit diagram of an isolated converter according to aseventh embodiment of the present invention.

FIG. 16 shows the waveform of the detection voltage and the controlsignal of the present invention.

FIG. 17 shows the waveform of D1 signal, TX signal and RX signal.

FIG. 18 is a circuit diagram of an isolated converter according theeighth embodiment of the present invention.

FIG. 19 is the internal circuit diagram of the on-time regulator andother components of the isolated converter of the eighth embodiment ofthe present invention.

FIG. 20 shows the waveforms of DE, P2, clk and P3 signals of the eighthembodiment of the present invention.

FIG. 21 is a circuit diagram of an isolated converter according to aninth embodiment of the present invention.

FIG. 22 is the internal circuit diagram of the on-time regulator andother components of the ninth embodiment of the present invention.

FIG. 23 shows the waveform DE1, P1, clk1, DE2, P2, clk2 and P4 signalsof the ninth embodiment of the present invention.

FIG. 24 shows the waveform of DOWN, LD, B1, B2, UP, F and I_(O) of theninth embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 2 is a circuit diagram of an isolated converter according to afirst embodiment of the present invention. The constant on-time (COT)isolated converter is connected to an input terminal 26 to receive aninput voltage V_(IN). The converter comprises a transformer 28 connectedto the input terminal 26 at its primary side and to an output capacitor30 and a load 31 through a diode 29 at its secondary side. The anode ofdiode 29 is connected to the secondary side of the transformer 28 whilethe cathode is connected to the output capacitor 30 and load 31. Thesecondary side of the transformer 28 and the load 31 are connected to aprocessor 32, which receives a start-up voltage S and an output voltageV_(O) or an output current I_(O) across load 31 and thus generates acontrol signal C. The transmission medium between the primary side andthe secondary side of the transformer 28 may be electric, magnetic,piezoelectric element or light. Hence the processor 32 is connected toat least one coupling element 34, such as a capacitor, a transformer, apiezoelectric element or an optical coupling element, to transmit thecontrol signal C to the primary side. The primary side of thetransformer 28 and the coupling element 34 are connected to a driver 36connected to the input terminal 26. Driver 36 receives the controlsignal C through the coupling element 34 and amplifies it to generate afirst digital signal D1. Driver 36 also includes a circuit protectionfunction. The primary side of the transformer 28 and driver 36 areconnected to a first electronic switch 38, such as N-channel MOSFETs orbipolar junction transistor, which receives the first digital signal D1and accordingly changes its ON/OFF state to control the output voltageV_(O) and output current I_(O) generated via transformer 28 from theinput voltage V_(IN) through the diode 29. The duration, in which theelectronic switch remains in an ON/OFF state, is determined by the timetaken for the control signal C to change from negative to positive andthen from positive to negative, for example, as the control signal C isa pulse signal, when it changes from negative to positive, the firstelectronic switch 38 is turned on and remains on until the signal dropsand changes from positive to negative, hence the ON state is ended. Theswitch is turned off and remains off until the signal changes fromnegative to positive, thus it is turned on again. Driver 36 alsoreceives an input voltage V_(IN) from the input terminal 26 andgenerates a first pulse signal P1 to the first electronic switch 38changing the ON/OFF state of the switch to control the output voltageV_(O) and output current I_(O) across load 31 via transformer 28, whichfurther provides the start-up voltage S to the processor 32 to generatethe control signal C. When driver 36 receives the control signal Cthrough the coupling element 34, it stops generating the first pulsesignal P1.

Processor 32 comprises an electrical signal extractor 40 and acontroller 42. The electrical signal extractor 40 is connected to thelow potential VSS, the secondary side of the transformer 28 and the load31, thus capturing a feedback voltage DV or a detection voltage DScorresponding to the output current I_(O). The controller 42 isconnected to the coupling element 34, the secondary side of thetransformer 28 and the electrical signal extractor 40. The controller 42receives the start-up voltage S and the feedback voltage DV or detectionvoltage DS from the electrical signal extractor 40 and thus generatesthe control signal C. Referring to FIG. 2 and FIG. 3A, the controller 42is provided with a preset reference voltage, hence when the feedbackvoltage DV is less than the reference voltage, the control signal C is asecond pulse signal P2 with at least one cycle, i.e., the waveform ofplural cycles appearing within time period T1 as shown in FIG. 3A. Thesecond pulse signal P2 in each of the first half cycle is at a highvoltage level and in each of the second half cycle is at a low voltagelevel. When the feedback voltage DV is greater than the referencevoltage, i.e., within time period T2, the control signal C is at the lowvoltage level. Similarly, when the detection voltage DS is less than thereference voltage, the control signal C is the second pulse signal P2 ofat least one cycle. The second pulse signal P2 in each of the first halfcycle is at the high voltage level and in each of the second half cycleis at the low voltage level. When the detection voltage DS is greaterthan the reference voltage, i.e., within time period T2, the controlsignal C is at the low voltage level.

As shown in FIG. 3B, the moment when the feedback voltage DV is lessthan the reference voltage, the control signal C sends out a singlecycle second pulse signal P2 such as the waveform within a preset periodT_(min) of the controller 42. The second pulse signal P2 in the firsthalf cycle is at the high voltage level and in the second half cycle isat the low voltage level, wherein a duration of the high voltage levelis determined by the controller 42 in the secondary side. Within thepreset period T_(min) when the feedback voltage DV is greater than thereference voltage, the control signal C will not send out the nextsecond pulse signal P2 until the feedback voltage DV is less than thereference voltage. Similarly, when the detection voltage DS is less thanthe reference voltage, the control signal C sends out the single cyclesecond pulse signal P2 within the preset period T_(min) of controller42. The second pulse signal P2 in the first half cycle is at a highvoltage level and in the second half cycle is at a low voltage level,wherein the duration of the high voltage level is determined by thecontroller 42 in the secondary side. Within the preset period T_(min)when the detection voltage DS is greater than the reference voltage, thecontrol signal C will not send out the next second pulse signal P2 untilthe detection voltage DS is less than the reference.

The start-up mode of operation of the first embodiment is described asfollows. First, driver 36 receives an input voltage V_(IN) from theinput terminal 26 generating a first pulse signal P1 transmitted to thefirst electronic switch 38, which changes its ON/OFF state accordinglyin order to control the output voltage V_(O) and output current I_(O)across load 31. The output voltage V_(O) and output current I_(O) aregenerated via transformer 28 through the diode 29. The start-up voltageS is also sent to controller 42 via transformer 28. Then, the electricalsignal extractor 40 retrieves either the feedback voltage DV from theoutput voltage V_(O) or the detection voltage DS corresponding to theoutput current I_(O), and send it to the controller 42 which generatesthe control signals C based on the feedback voltage DV or the detectionvoltage DS and the start-up voltage S. The duration between the momentthe control signal C changes from negative to positive and the momentthe control signal C changes from positive to negative determines theduration of the ON/OFF state of the first electronic switch 38. Thecoupling element 34 transmits the control signal C from the secondaryside to driver 36 in the primary side. When driver 36 receives thecontrol signal C, it amplifies the control signal C to produce a firstdigital signal D1 and stops generating the first pulse signal P1.Finally, the first electronic switch 38 receives the first digitalsignal D1 and accordingly changes its ON/OFF state to control thetransformer 28 receiving the input voltage V_(IN) thus regulating theoutput voltage V_(O) and output current I_(O) via the diode 29. In priorart, compensation circuit is necessary to compensate for gain margin andphase margin to ensure the stability of the output voltage of thedevice. The present invention does not require any compensation circuit,thus avoiding the complicated technology of gain margin and phase marginadjustment. Yet the present invention is able to detect the outputvoltage V_(O) or the output current I_(O) directly and to transmit theinformation to the primary side, using the information from thesecondary side to determine the time for the switch on the primary sideto turn on or off, therefore instantly regulating the output voltage andoutput current to attain a fast load transients response. Furthermore,the present invention utilizes the coupling element to transmitinformation from the output voltage or the output current from thesecondary side to the primary side, thus does not need to use anyencoder or decoder unit as well as encoding or decoding technology,while effectively isolating the signal on the primary side and on thesecondary side, allowing the secondary side independent regulation ofthe output voltage V_(O) and output current I_(O).

FIG. 4 is a circuit diagram of an isolated converter according to asecond embodiment of the present invention. Referring to FIG. 4, inorder to improve the efficiency of the system, a second electronicswitch 44, for example an N-channel power MOSFET, is replaced for thediode 29 of FIG. 2 as synchronous rectifiers. In this embodiment, thesecondary side of the transformer 28 is connected directly to the load31. Further, the second electronic switch 44 is connected between thesecondary side of the transformer 28 and the load 31, and is connectedto the controller 42. When the controller 42 generates the controlsignal C, it also generates a second digital signal D2, according toeither the feedback voltage DV or the detection voltage DS and thestart-up voltage S, and sends the second digital signal D2 to the secondelectronic switch 44 to change the ON/OFF state of the second electronicswitch 44, such that the second electronic switch 44 is in oppositeON/OFF states of the first electronic switch 38 or both of the firstelectronic switch 38 and the second electronic switch 44 are turned off,hence the transformer 28 receives the input voltage V_(IN) to regulatethe output voltage V_(O) and output current I_(O).

The start-up mode operation of the system of FIG. 4 is described asfollows. First, driver 36 receives an input voltage V_(IN) from theinput terminal 26 and then generates a first pulse signal P1 to thefirst electronic switch 38 thus the ON/OFF state of the first electronicswitch 38 is changed accordingly to control the input voltage V_(IN)applied to the transformer 28 and through the second electronic switch44 generating the output voltage V_(O) and output current I_(O) acrossthe load 31. Furthermore, the start-up voltage S is applied to thecontroller 42 via the transformer 28. Then, the electrical signalextractor 40 retrieves the feedback voltage DV of the output voltageV_(O) or the detection voltage DS corresponding to the output currentI_(O) and sends to the controller 42 that also receives the start-upvoltage S and thus generates the control signal C and the second digitalsignal D2. The duration for the ON/OFF state of the first electronicswitch 38 is determined by the duration of the control signal C betweenthe moment it changes from negative to positive and the moment itchanges from the positive to negative. The second electronic switch 44receives the second digital signal D2 and changes its ON/OFF state, andthe coupling element 34 transmits the control signal C from thesecondary side to the driver 36 on the primary side. When driver 36receives the control signal C, it amplifies the control signal C toproduce a first digital signal D1 and stops generating the first pulsesignal P1. Finally, the first electronic switch 38 receives the firstdigital signal D1 and accordingly switches its ON/OFF state to controlthe transformer 28 receiving the input voltage V_(IN) thus regulatingthe output voltage V_(O) and output current I_(O).

FIG. 5 is a circuit diagram of an isolated converter according to athird embodiment of the present invention. Referring to FIG. 5, thestart-up voltage S is applied to the controller 42 by an externalcircuit 46 connected to controller 42 instead of provided by thetransformer 28 as described in FIG. 2. In operation, assuming the outputvoltage V_(O) and output current I_(O) already applied across the load31 and the external circuit 46 already supplied the start-up voltage Sonto the controller 42, thereafter the electrical signal extractor 40retrieves and sends the feedback voltage DV of the output voltage V_(O)or the detection voltage DS corresponding to the output current I_(O) tothe controller 42. Upon receiving the feedback voltage DV of the outputvoltage V_(O) or the detection voltage DS corresponding to the outputcurrent I_(O), together with the start-up voltage S, the controller 42generates the control signal C accordingly, wherein the duration for theON/OFF state of the first electronic switch 38 is determined by theduration of the control signal C between the moment it changes fromnegative to positive and the moment it changes from the positive tonegative. Then, the coupling element 34 transmits the control signal Cfrom the secondary side to the driver 36 on the primary side. Driver 36receives the control signal C and amplifies it to produce a firstdigital signal D1 and sends the first digital signal D1 to the firstelectronic switch 38, which then accordingly changes its ON/OFF state tocontrol the transformer 28 receiving the input voltage V_(IN), henceregulating the output voltage V_(O) and output current I_(O) through thediode 29.

FIG. 6 is a circuit diagram of an isolated converter according to afourth embodiment of the present invention. As shown in FIG. 6, thestart-up voltage S is applied to the controller 42 by an externalcircuit 46 instead of the transformer 28 as shown in FIG. 4. Inoperation, assuming the output voltage V_(O) and output current I_(O)already applied across the load 31 and the external circuit 46 alreadysupplied the start-up voltage S to the controller 42, thereafter theelectrical signal extractor 40 retrieves the feedback voltage DV of theoutput voltage V_(O) or the detection voltage DS corresponding to theoutput current I_(O) and sends it to the controller 42. Upon receivingthe feedback voltage DV of the output voltage V_(O) or the detectionvoltage DS corresponding to the output current I_(O), together with thestart-up voltage S, the controller 42 generates the control signals Cand the second digital signal D2 accordingly, wherein the duration forthe ON/OFF state of the first electronic switch 38 is determined by theduration of the control signal C between the moment it changes formnegative to positive and the moment it changes from positive tonegative. The second electronic switch 44 receives the second digitalsignal D2 to change its ON/OFF state, and the coupling element 34transmits the control signal C from the secondary side to the driver 36on the primary side. The driver 36 receives the control signal C andamplifies it to produce the first digital signal D1 that is then sent tothe first electronic switch 38. The first electronic switch 38accordingly switches its ON/OFF state to control the transformer 28receiving the input voltage V_(IN) thus regulating the output voltageV_(O) and the output current I_(O).

FIG. 7 and FIG. 8 illustrate alternative circuit diagrams of theelectrical signal extractor 40. As shown in FIG. 7, the electricalsignal extractor 40 is in the form of voltage divider 48 that isconnected to the secondary side of transformer 28 through the diode 29,or it can also be connected directly to the secondary side of thetransformer 28, and is able to capture the feedback voltage DV of theoutput voltage V_(O). As shown in FIG. 8, the electrical signalextractor 40 is a resistor 50 that is connected to the secondary side oftransformer 28 through the diode 29, or it can also be connecteddirectly to the secondary side of the transformer 28. When the outputcurrent I_(O) flows through the resistor 50, the detection voltage DS isgenerated via the resistor 50.

Referring to FIG. 9, driver 36 includes a comparator 52 and a resistor54 connected at the positive input terminal of the comparator 52 whilethe other end of the resistor 54 is grounded. The controller 42 includesa switching control circuit 56, a bias circuit 58, a buffer 60, aninverter 62, a third electronic switch 64 and a fourth electronic switch66. The switching control circuit 56 is connected to the buffer 60 andthe inverter 62, which are connected to the third electronic switch 64and fourth electronic switch 66 respectively. The bias circuit 58 isconnected to the third electronic switch 64. The third electronic switch64 and fourth electronic switch 66 are connected to resistor 54 throughcoupling element 34. The signal between the resistor 54 and the positiveinput of comparator 52 is referred as the RX signal and the signalbetween the coupling element 34 and the third electronic switch 64 isreferred as signals TX. The switching control circuit 56, through thebuffer 60 and the inverter 62, controls the third electronic switch 64and fourth electronic switch 66 so that their ON/OFF states areopposite. When feedback voltage DV is smaller than the reference voltageof controller 42, the switching control circuit 56 turns on the thirdelectronic switch 64 and turns off the fourth electronic switch 66through buffer 60 and the inverter 62, resulting in a current that issent, by the bias circuit 58, across the third electronic switch 64, thecoupling element 34, the resistor 54 and the coupling element 34 to thelow potential VSS. The comparator 52 receives the RX signal, and thusgenerates a first digital signal D1. After a given period of time, theswitching control circuit 56 turns off the third electronic switch 64and turns on the fourth electronic switch 66 through buffer 60 and theinverter 62, hence the current flows sequentially through the couplingelement 34, resistor 54, coupling element 34 and the fourth electronicswitch 66. The waveforms of the RX signal, TX signal, feedback voltageDV and the first digital signal D1 are shown in FIG. 10. As shown in thefigure, when the feedback voltage DV is lower than the referencevoltage, a high voltage level of the first digital signal D1 isgenerated with very short delay time.

Referring to FIG. 9 and FIG. 11, to achieve a small size system, driver36, the controller 42 and the coupling element 34 may be integrated inone package. As shown in FIG. 11, the package includes a firstsemiconductor chip 68, a dielectric layer 70 and a second semiconductorchip 72 stacked together. The first semiconductor chip 68 includes thecontroller 42, the second semiconductor chip 72 includes the driver 36,while the coupling element, for example a capacitor, are formed by aconductive layer on the first semiconductor chip 68, dielectric layer 70and a conductive layer on the second semiconductor chip 72, where theconductive layer of the first semiconductor chip 68 and the secondsemiconductor chip 72 can be a metal layer, or a lead frame. When thecoupling element 34 is a transformer, a piezoelectric element or anoptical coupling element, similar method can be used to integrate itinto a package structure, in order to reduce the footprint on theprinted circuit board, and the bill of material (BOM) cost.

In FIG. 8, the electrical signal extractor 40 is a resistor 50. Assumingthe reference voltage of controller 42 is 250 mV, the DC component ofthe output current I_(O) through the resistor 50 is 2.5 amps, whichmeans the resistance of the resistor 50 must be set to 0.1 ohms, inorder to output an accurate control signal C. However, the resistor 50is in the main output path, so it cannot be too large, or else it willincrease the loss in output efficacy; when the resistor is too small,the reference voltage of controller 42 must also be small, otherwise itis not able to determine the ripple signal of the output current I_(O)in order to output an accurate control output signal C. However, whenthe reference voltage of the controller 42 is set very small, itscircuit will be difficult to design.

FIG. 12 is a circuit diagram of an isolated converter according to afifth embodiment of the present invention. Referring to FIG. 12, theconstant on-time isolated converter is connected to an input terminal 74to receive an input voltage V_(IN). This constant on-time isolationconverter comprises a transformer 76 with primary side and secondaryside, where the primary side is connected to the input terminal 74 andthe secondary side is connected to a diode 77, a load 78 and an outputcapacitor 79. The anode of the diode 77 is connected to the secondaryside of transformer 76 while its cathode is connected to load 78 and theoutput capacitor 79. There is a ripple signal on the secondary side ofthe transformer 76, which results in an output voltage V_(O) and anoutput current I_(O) across the load 78. This ripple signal has an ACcomponent and a DC component. The average value of the ripple signalvoltage is the voltage value of the DC component. The voltage value ofthe AC component is obtained by subtracting the voltage value of the DCcomponent from the voltage of the ripple signal. The cathode of diode77, the secondary side of the transformer 76 and load 78 are connectedto a processor 80, which captures the output AC voltage A of the ACcomponent and the output current I_(O) of the ripple signal. Processor80 is preset with a reference voltage, the processor 80 converts theoutput current I_(O) to a process voltage K. Since the output currentI_(O) is an AC/DC signal, the process voltage K is also an AC/DC voltagesignal, with the DC component being much larger than the AC component.Therefore, the process voltage K includes an AC component and a DCcomponent and its average voltage value is the voltage value of the DCcomponent. The processor 80 utilizes a filter 92 to substrate thevoltage value of the DC component of the feedback voltage DV, thusobtaining the AC voltage A of the AC component. The processor 80 presetsthe voltage value of the DC component of the process voltage K to beequal to or slightly higher than the reference voltage and generates acontrol signal C according to the AC voltage A and the process voltageK. For example, the processor 80 combines the AC voltage A and theprocess voltage K to generate a control voltage CV and based on this andthe reference voltage generates the control signal C. The transmissionmedium between the primary side and the secondary side can beelectrical, magnetic, piezoelectric or optical components. The processor80 is connected to at least one coupling element 82, such as acapacitor, a transformer, a piezoelectric element or an optical couplingelement, which is connected to the primary side and the secondary sideof the transformer 76 to transmit the control signal C from thesecondary side to the primary side. The input terminal 74, the primaryside of the transformer 76 and the coupling element 82 are connected toa driver 84, which receives the control signal C and then amplifies itto generate a digital signal D. The primary side of the transformer 76and the driver 84 are connected to an electronic switch 86, such asN-channel MOSFET or a bipolar junction transistor, which receives thedigital signal D and accordingly changes its ON/OFF state to control theinput voltage V_(IN) received by the transformer 76, and then toregulate the output voltage V_(O) and output current I_(O) through thediode 77, where the duration of the electronic switch 86 ON/OFF state isdetermined by the moment the control signal C changes from negative topositive and the moment it changes from positive to negative, forexample, if the control signal C is a clock signal, when the clocksignal changes from negative to positive, electronic switch 86 is turnedon and remains on until the clock signal goes from positive to negative,i.e., the ON state of the electronic switch 86 is ended thus theelectronic switch 86 is turned off and remains off until when the clocksignal changes from negative to positive again, i.e., the OFF state ofelectronic switch 86 is ended, and it is turned on again.

Driver 84 receives the input voltage V_(IN) from the input terminal 74and generates a first pulse signal P1 to the electronic switch 86, whichchanges the ON/OFF state of the electronic switch 86 accordingly, tocontrol the input voltage V_(IN) received by transformer 76, whichgenerates the ripple signal, the output voltage V_(O) and the outputcurrent I_(O) through diode 77. Then processor 80 generates a controlsignal C, sends it to the driver 84 through the coupling element 82,hence the driver 84 stops generating the first pulse signal P1.

Referring to FIG. 3B and FIG. 12, the processor 80 comprises acurrent-voltage converter 88, a voltage divider 90, a filter 92, anadder 94 and a controller 96. Current-voltage converter 88 is connectedto a load 78 and retrieves and converts the output current I_(O) intothe process voltage K. Voltage divider 90 is connected to a lowpotential VSS, the cathode of diode 77, the secondary side oftransformer 76 and the load 78. The voltage divider 90 receives theoutput voltage V_(O) and captures the feedback voltage DV. Filter 92 isconnected to the voltage divider 90, thus receives and filters thefeedback voltage DV to produce AC voltage A. The adder 94 is connectedto the filter 92 and the current-voltage converter 88, thus receives andcombines the AC voltage A and process voltage K together to generate acontrol voltage CV. The controller 96, which has a preset referencevoltage and a preset period Tmin, is connected to the low potential VSS,the coupling element 82, the adder 94, the secondary side of thetransformer 76 and the load 78, so as to receive the control voltage CV,and with the reference voltage, generates the control signal C. When thecontrol voltage CV is less than the reference voltage, within the presetperiod Tmin, the control signal C is a second pulse signal P2 of atleast one cycle, where the voltage in each of the first half cycle ofthe second pulse signal is at a high voltage level and the voltage ineach of the second half cycle is at a low voltage level. Then, at theend of the preset period Tmin, when the control voltage CV is greaterthan the reference voltage, the control signal C is at a low voltagelevel. Current-voltage converter 88 comprises a resistor 98 and anamplifier 100. The resistor 98 is connected to the load 78 and the lowpotential VSS, and the output current I_(O) flows through the resistor98 thus generating the detection voltage DS across the resistor 98.Amplifier 100 is connected to adder 94, load 78 and resistor 98,receives and amplifies the detection voltage DS generating the processvoltage K.

In operation of this embodiment, firstly, the driver 84 receives theinput voltage V_(IN) from the input terminal 74 generating a first pulsesignal P1 to the electronic switch 86, thus the ON/OFF state of theelectronic switch 86 is changed accordingly, which controls the inputvoltage V_(IN) received by the transformer 76 and through the diode 77generating a ripple signal on the secondary side of the transformer 76,and at the same time generating an output voltage V_(O) and an outputcurrent I_(O) across the load 78, and via transformer 76 providing powerto the controller 96. Then, the output current flows through theresistor 98 generating the detection voltage DS across the resistor 98,in addition, the voltage divider 90 receives the output voltage V_(O)and captures the feedback voltage DV of the output voltage V_(O). Theamplifier 100 receives and amplifies the detection voltage DS and thusgenerates the process voltage K, while the filter 92 receives andfilters the feedback voltage DV producing the AC voltage A. Then, theadder 94 receives and combines the AC voltage A and the process voltageK generating the control voltage CV. The controller 96 receives thecontrol voltage CV and, with the reference voltage, generates thecontrol signal C. For example, when the control voltage CV is less thanthe reference voltage, the control signal C, in the preset time periodTmin, is the second pulse signal P2 of at least one cycle. Then, at theend of the preset time period Tmin, when the control voltage CV isgreater than the reference voltage, the control signal C is at a lowvoltage level. The controller 96 uses the duration between the crossingof the control signal C from negative to positive and from positive tonegative to set the time for the ON/OFF state of the electronic switch86. The coupling element 82 transmits the control signal C from thesecondary side to the driver 84 of the primary side. When the driver 84receives the control signals C, it stops generating the first pulsesignal P1, and amplifies the control signal C to produce the digitalsignal D. Finally, the electronic switch 86 receives the digital signalD, and accordingly changes its ON/OFF state to control the input voltageV_(IN) received by the transformer 76, and then through the diode 77regulates the output voltage V_(O) and output current I_(O).

FIG. 13 displays the waveforms of the current M through the electronicswitch 86, the current DI through the diode 77, the digital signal D andthe detection voltage DS. The AC voltage A signal of the ripple signalis produced from the feedback voltage DV, but can also be obtained fromthe detection voltage DS or secondary diode current DI. In addition,referring to FIG. 8 and original setting of the reference voltage andoutput current I_(O), the resistance of the resistor 50 must be set to0.1 ohms. However, in this embodiment, by using voltage divider 90,filter 92, adder 94 and the amplifier 100, the resistance of theresistor 98 can be set to 10 milli-ohms to match the reference voltageof 25 mV and the DC component of the output current I_(O) which is 2.5amps. Thus, the loss of output efficacy is reduced, and the referencevoltage of controller 96 need not be set very small, so that the circuitof controller 96 is easy to design.

FIG. 14 is a circuit diagram of an isolated converter according to asixth embodiment of the present invention. Different from the fifthembodiment, where the current-voltage converter 88 consists of theresistor 98 and the amplifier 100, in this embodiment, thecurrent-voltage converter 88 is a Hall element connected to the load 78to retrieve the output current I_(O) and, by adjusting the appropriatemagnetic field, the output current I_(O) is converted to the processvoltage K. The operations of other components of the system are the sameas that in the fifth embodiment.

Referring back to FIG. 4, during the start-up mode, the first electronicswitch 38 receives the first pulse signal P1 generated by driver 36 andthus its ON/OFF state is changed to control the power supplied to thecontroller 42 provided by transformer 28, so that controller 42generates the control signal C and the second digital signal D2synchronously. Theoretically, the first electronic switch 38 and thesecond electronic switch 44 receive the control signal C and the seconddigital signal D2 respectively such that their ON/OFF states areopposite. However, if the coupling element 34 is damaged, the controlsignal C cannot be transmitted from the secondary side to the primaryside. Since the driver 36 does not receive the control signals C, itwill continue to generate the first pulse signal P1 to the firstelectronic switch 38. As a result, the first electronic switch 38 andthe second electronic switch 44 are unable to synchronize, and may evenbe turned on at the same time, resulting in damage to the entire system.

The problem mentioned above is solved by the system of FIG. 15 accordingto a seventh embodiment of the present invention. As shown in FIG. 15,the constant on-time isolated converter is connected to an inputterminal 102 to receive an input voltage V_(IN). The constant on-timeconverter comprises a transformer 104 with its primary side connected tothe input terminal 102 and its secondary side connected to an outputcapacitor 105 and a load 106 with an output voltage V_(O) and an outputcurrent I_(O) applying across the load 106. The primary side oftransformer 104 and input terminal 102 are connected to a driver 108 toreceive an input voltage V_(IN) thus generating a plurality of wake-upsignals W sequentially. Driver 108 is connected to at least one couplingelement 110, such as capacitors, transformers, a piezoelectric elementor an optical coupling element, which is connected to the primary sideand the secondary side of transformer 104, to transmit the wake-upsignal W to the secondary side. The coupling element 110, the secondaryside of the transformer 104, a low potential VSS, the output capacitor105 and the load 106 are connected to processor 112, which receiveseither the output voltage V_(O) or output current I_(O) and the wake-upsignal W, and generates and transmits a control signal C to the driver108 via the coupling element 110, thus the driver 108 amplifies thecontrol signal C to produce a first digital signal D1. The primary sideof the transformer 104 and driver 108 are connected to a firstelectronic switch 114, such as N-channel MOSFET or a bipolar junctiontransistor, which receives the first digital signal D1 and accordinglychanges its ON/OFF state to control the input voltage V_(IN) received bythe transformer 104 from input terminal 102, thereby regulating theoutput voltage V_(O) and output current I_(O). Specifically, when thefirst electronic switch 114 is turned on, the transformer 104 starts tostore energy thus the output voltage decreases. When the firstelectronic switch 114 is turned off, the transformer 104 starts torelease energy thus the output voltage increases. Additionally, theon/off duration of the first electronic switch 114 is determined fromthe instance the control signal C on the secondary side crossing fromthe negative to positive to the instance the control signal C crossingfrom positive to negative. For example, when the control signal C is aclock signal, when it crosses from the negative to positive, the firstelectronic switch 114 is turned on and remains on until the clock signalcrosses from positive to negative. At this time the ON state of thefirst electronic switch is ended and it is turned off, and remains offuntil the clock signal crosses from negative to positive, i.e., when theOFF state is ended, thus the first electronic switch 114 is turned onagain. Driver 108 receives an input voltage V_(IN) from the inputterminal 102 generating a first pulse signal P1 to the first electronicswitch 114, as such the first electronic switch 114 changes its ON/OFFstate accordingly to control the input voltage V_(IN) received by thetransformer 104 and produce an output voltage V_(O) and output currentI_(O) flowing across load 106, and via the transformer 104 providespower to the processor 112 to generates the control signal C. When thefirst electronic switch 114 is turned on, transformer 104 stores energy,the output capacitor 105 provides energy to the processor 112 togenerate the control signal C and generates the output voltage V_(O) andoutput current I_(O). When the first electronic switch 114 is turnedoff, the transformer 104 starts to release the stored energy to theoutput capacitor 105 and provides energy to the processor 112 togenerate the control signal C, and thus the transformer 104 produces theoutput voltage V_(O) and output current I_(O). Next, when the driver 108receives the control signal C through the coupling element 110, it stopsgenerating the first pulse signal P1 and the wake-up signal W.

In FIG. 15, the processor 112 comprises an electrical signal extractor116 and a controller 118. Electrical signal extractor 116 is connectedto a low potential VSS, the secondary side of the transformer 104 andload 106 to capture the output voltage V_(O) or the detection voltage DEcorresponding to the output current I_(O). The controller 118 isconnected to the coupling element 110, the secondary side of thetransformer 104 and electrical signal extractor 116 to receive thedetection voltage DE and the wake-up signal W, and then generates thecontrol signal C based on the detection voltage signal DE and wake-upsignal W. Referring to FIG. 15 and FIG. 16, since the controller 118 ispreset with a reference voltage, when the detection voltage DE issmaller than the reference voltage, the control signal C within a presetperiod T_(min) is a second pulse signal P2 of at least one cycle, inwhich the voltage in each of the first half cycle of the second pulsesignal P2 is at a high voltage level, and in each of the second halfcycle is at a low voltage level. Then, at the end of a preset timeperiod T_(min), when detection voltage DE is larger than the referencevoltage, the control signal C is at a low voltage level.

A second electronic switch 120, such as N-channel MOSFET, is connectedto the secondary side of transformer 104, the load 106, the controller118, the low potential VSS and the electrical signal extractor 116. Whenthe controller 118 generates the control signal C, it also generates asecond digital signal D2 based on the detection voltage signal DE andthe wake-up signal W to the second electronic switch 120, thus changingthe ON/OFF states of the second electronic switch 120 so that the firstelectronic switch 114 and the second electronic switch 120 are inopposite ON/OFF states or both are turned off, as such the transformer104 receives the input voltage V_(IN) to regulate the output voltageV_(O) and output current I_(O).

The start-up operation of the seventh embodiment is described asfollows. First, driver 108 receives an input voltage V_(IN) from aninput terminal 102 generating a first pulse signal P1 to the firstelectronic switch 114, thus changing the ON/OFF state of the firstelectronic switch 114 accordingly to control the input voltage V_(IN)received by the transformer 104, and through the second electronicswitch 120 to produce an output voltage V_(O) and output current I_(O)on the load 106. Meanwhile, based on the first pulse signal P1, thefirst electronic switch 114 provides energy to the controller 118 viatransformer 104, while driver 108 produces a wake-up signal W using theinput voltage. Then, electrical signal extractor 116 captures either theoutput voltage V_(O) or detection voltage DE corresponding to the outputcurrent I_(O) and then send to the controller 118. Controller 118receives the wake-up signal W, through the coupling elements 110, andthe detection voltage DE, and with the energy supplied by transformer104 generates a control signal C and the second digital signal D2accordingly, and the duration between the instance the control signal Ccrossing from negative to positive to the instance when the controlsignal crossing from positive to negative is used to determine theduration for switching the ON/OFF state of the first electronic switch114. Then, the second electronic switch 120 receives the second digitalsignal D2 and changes its ON/OFF state, and the coupling element 110transmits the control signal C from the secondary side to the driver 108in the primary side. When driver 108 receives the control signal C, itstops generating first pulse signal P1 and the wake-up signal W, andamplifies the control signal C to produce a first digital signal D1.Finally, the first electronic switch 114 receives the first digitalsignal D1, and accordingly changes its ON/OFF state to control the inputvoltage V_(IN) received by the transformer 104, hence regulating theoutput voltage V_(O) and output current I_(O).

Referring to FIG. 15 and FIG. 17, the signal between the couplingelement 110 and the driver 108 is referred to as the RX signal and thatbetween the coupling element 110 and the controller 118 as the TXsignal, as such TX signal also represents the control signal C. Duringperiod T1, in which RX signal represents a complex wakeup signal W, thecontroller 118 has not yet received wake-up signal W, so there is no TXsignal generation. Next, in period T2, since the controller 118 receivesthe wake-up signal W, it generates a control signal C and transfers itthrough a coupling element 110 to the driver 108. Therefore, at thistime the signal RX will be synchronized with the TX signals. On theother hand, if the coupling element 110 is damaged, the wake-up signal Wcannot be transmitted through the coupling element 110 to the controller118. If controller 118 does not receive the wake-up signal W, it willnot be able to generate the control signal C and the second digitalsignal D2, then the whole system will not be operated, hence avoidingdamage to the system.

In FIG. 2, when the system operates in discontinuous mode, the switchingfrequency of the first electronic switch 38 is represented by formula(1):

$\begin{matrix}{f = \frac{2 \times I_{o} \times L \times V_{o}}{V_{IN}^{2} \times t_{on}^{2}}} & (1)\end{matrix}$

Where V_(IN) is the input voltage, V_(O) is the output voltage, I_(O) isthe output current, L is the inductance of the transformer 28, t_(on) isthe on-duration when the first electronic switch 38 is turned on. Whenthe load 31 is unchanged, and if t_(on) also remains unchanged, then theswitching frequency f is inversely proportional to the input voltageV_(IN). Thus, when the input voltage V_(IN) increases, the switchingfrequency f will decrease accordingly. However, when the switchingfrequency is too low, the transformer 28 becomes saturated, there willbe no inductance, and then it will be burned.

FIGS. 18-20 illustrate the eighth embodiment of the present invention,which can reduce the degree of changes to the switching frequency inresponse to different input voltages to avoid damage to the system. Theconstant on-time isolated converter of the present invention isconnected to an input terminal 122 to receive an input voltage V_(IN).This constant on-time isolated converter comprises a transformer 124with a primary side and a secondary side, where the primary side isconnected to the input terminal 122 and the secondary side is connectedto an output capacitor 126 in parallel to load 128. A driver 130 isconnected to the input terminal 122 and receives an input voltage V_(IN)generating a first pulse signal P1. Driver 130 and the primary side ofthe transformer 124 are connected to a first electronic switch 132, suchas N-channel MOSFET or a bipolar junction transistor, which receives thefirst pulse signal P1 and accordingly changes its ON/OFF state tocontrol the input voltage V_(IN) received by the transformer 124 toproduce an output voltage V_(O) and an output current I_(O) across load128, and also controls the sampling voltage SM containing the inputvoltage V_(IN) generated on the secondary side of transformer 124. Aprocessor 134 is connected between the secondary side of the transformer124 and the load 128, and is preset with a first reference voltage VR1and a period T_(min). Processor 134 receives either the output voltageV_(O) or the output current I_(O), the sampling voltage SM, and alsocaptures the detection voltage DE corresponding to either the outputvoltage V_(O) of the output current I_(O). When the detection voltage DEis less than the first reference voltage VR1, processor 134 generates asecond pulse signal P2 within the preset period T_(min) according to theinput voltage V_(IN) in the sampling voltage SM. This second pulsesignal P2 is of at least one cycle in which its voltage in each of thefirst half cycle is at a high voltage level, and that in each of thesecond half cycle is at a low voltage level. Processor 134 and driver130 are connected to the coupling element 136, which can be capacitors,transformers, piezoelectric element or optical coupling element.Coupling element 136 is positioned between the primary side and thesecondary side, where the coupling element 136 transmits the secondpulse signal P2 to the driver 130 at the primary side to stop the driver130 from generating the first pulse signal P1. The driver 130 furtheramplifies the second pulse signal P2 to generate a first digital signalD1 and transmits the first digital signal D1 to the first electronicswitch 132. The first electronic switch 132 changes its ON/OFF stateaccordingly to control the input voltage V_(IN) received by transformer124 from the input terminal 122 for regulating the output voltage V_(O)and output current I_(O). The duration of the first electronic switch132 ON/OFF state is determined from the instance the second pulse signalP2 at the secondary side crosses from negative to positive to theinstance it crosses from positive to negative, for example when thesecond pulse signal P2 is a clock signal, at the time it crosses fromnegative to positive, the first electronic switch 132 is turned on andremains on until the clock signal crosses from the positive to negative,i.e., the first electronic switch's ON state is ended and it is turnedoff. The first electronic switch remains off until the clock signalcrosses from negative to positive, hence the first electronic switch 132is turned on again. Since the ON/OFF state duration of the firstelectronic switch 132 is dependent on the second pulse signal P2, whichis dependent on the input voltage V_(IN), the settings for the secondpulse signal P2 and the input voltage V_(IN) can be adjusted such thatthe higher the input voltage V_(IN), the shorter time the firstelectronic switch 132 remaining in ON state, and the lower the inputvoltage, the longer time the first electronic switch 132 staying in ONstate.

As shown in FIG. 18, the processor 134 comprises an electrical signalextractor 138, an on-time regulator 140 and a controller 142. Theelectrical signal extractor 138 connects to a low potential VSS, thesecondary side of the transformer 124 and the load 128 to receive theoutput voltage V_(O) or output current I_(O), and to extract thedetection voltage DE. The on-time regulator 140 is connected to thesecondary side of the transformer 124 to receive and captures thesampled voltage SM. The controller 142 is connected to a low potentialVSS, the on-time regulator 140, a coupling element 136, the secondaryside of the transformer 124 and the electrical signal extractor 138. Thecontroller 142 is preset with a first reference voltage VR1 and a periodT_(min) to receive a detection voltage DE. When the detection voltage DEis less than the first reference voltage VR1, the controller 142generates a second pulse signal P2 and a clock signal clk correspondingto the preset period T_(min). When the system is operating in thediscontinuous mode, the switching frequency of the first electronicswitch 132 is represented by formula (2):

$\begin{matrix}{{i.\mspace{14mu} f} = \frac{2 \times I_{o} \times L \times V_{o}}{V_{IN}^{2} \times t_{on}^{2}}} & (2)\end{matrix}$

Where V_(IN) is the input voltage, V_(O) is the output voltage, I_(O) isthe output current, L is the inductance of the transformer 124, t_(on)is the time of the first electronic switch 132 remaining the ON state.To avoid the transformer 28 being saturated when the switching frequencyis too low, in this embodiment, when the input voltage is higher, theon-time of the first electronic switch 132 is shorter and vice versa,thus reducing the changes in the switching frequency due to differentinput voltage V_(IN).

The clock signal clk is a positive pulse signal when the second pulsesignal P2 crosses from negative to positive, while the clock signal clkis a low level signal at other times. The on-time regulator 140 receivesthe clock signal clk and, together with the input voltage V_(IN),generates and transmits a third pulse signal P3 to the controller 142 sothat when the third pulse signal P3 changes from negative to positive,the second pulse signal P2 changes from positive to negative and remainsnegative at least until the end of the preset period T_(min), and thenwhen the clock signal appears as the next positive pulse signal, thesecond pulse signal P2 will again changes from negative to positive. Asecond electronic switch 144, such as N-channel MOSFET, is connectedbetween the secondary side of the transformer 124 and the load 128 andalso to the controller 142. When the controller 142 generates the secondpulse signal P2, it also generates a second digital signal D2accordingly to the second electronic switch 144, thus the ON/OFF stateof the first electronic switch 132 and the second electronic switch 144are opposite or both are turned off. To capture the input voltageV_(IN), the on-time regulator 140 can be connected to any node at thesecondary side of the transformer 124, for example, it may be connectedbetween the second electronic switch 144 and the transformer 124 andwhen the second electronic switch 144 is off, the on-time regulator 140receives the sampled voltage SM between the second electronic switch 144and the transformer 124.

As shown in FIG. 19, the on-time regulator 140 comprises a sample holder146, a dependent current source 148, a third electronic switch 150, acapacitor 152 and a comparator 154. Sample holder 146 is connected tothe secondary side of the transformer 124 to receive and capture thesampled voltage SM. The dependent current source 148 is connected to thesample holder 146 to receive the sample voltage SM generating adependent current based on the input voltage V_(IN) in sampled voltageSM. To achieve shorter ON-state time of the first electronic switch whenthe input voltage is higher and vice versa, the dependent current sourceis designed such that when the input voltage is higher, the dependentcurrent is also larger and when the input voltage is lower, thedependent current is smaller. The third electronic switch 150 isconnected to the controller 142 and dependent current source 148receiving the clock signal clk, and is turned on when the positive pulsesignal appears but is turned off at other times. Capacitor 152 isconnected in parallel with the third electronic switch 150 and isconnected in series to the dependent current source 148 for receiving adependent current depending on the ON/OFF state of the third electronicswitch 150 to store a dependent voltage PV. The capacitor 152 connectsto the comparator 154 and the controller 142 receiving a secondreference voltage VR2 at its negative input terminal and receiving thedependent voltage PV at its positive input terminal respectively,thereby producing a third pulse signal P3.

The start-up mode of operation of system in FIG. 18 is described asfollows. First, driver 130 receives the input voltage V_(IN) from theinput terminal 122 generating a first pulse signal P1 to the firstelectronic switch 132, which changes its ON/OFF states accordingly tocontrol the input voltage V_(IN) received by transformer 124 to producean output voltage V_(O) and output current I_(O) on load 128 through thesecond electronic switch 144. Meanwhile, the first pulse signal P1changes the ON/OFF state of the first electronic switch 132 to controlsampling voltage SM containing the input voltage V_(IN) generated at thesecondary side of transformer 124. When the first pulse signal P1 is ata high level signal, the first electronic switch 132 is turned on andthe transformer 124 stores energy while the output capacitor 126supplies energy to generate an output voltage V_(O) and an outputcurrent I_(O). When the first pulse signal P1 is at a low level signal,the first electronic switch 132 is turned off and the transformer 124releases energy to generate an output voltage V_(O), an output currentI_(O) and a sampling voltage SM, while the energy is stored in theoutput capacitor 126.

Then, the electrical signal extractor 138 captures the detection voltageDE corresponding to either the output voltage V_(O) or the outputcurrent I_(O) and sends it to the controller 142. The controller 142receives the detected voltage DE, and when the detection voltage DE isless than the first reference voltage VR1, the controller 142 generatesa second pulse signal P2 and a corresponding clock signal clk during thepreset period T_(min), and also generates and transfers a second digitalsignal D2 according to the second pulse signal P2 to the secondelectronic switch 144 to change its ON/OFF state. Meanwhile, the on-timeregulator 140 starts operating, while the second electronic switch 144is in OFF state. The first the sample holder 146 receives the samplingvoltage SM thus captures the input voltage V_(IN) from the samplingvoltage SM. Then, the dependent current source 148 receives the inputvoltage V_(IN) and generates a dependent current accordingly. Since theclock signal clk is a positive pulse signal, when the second pulsesignal P2 changes from negative to positive and is a low level signal,when the third electronic switch 150 receives the clock signal clk, thethird electronic switch 150 is only turned on when the positive pulsesignal appears otherwise it remains in OFF state. In other words, at thestart of the second pulse signal P2, the third electronic switch 150 isturned on, so that the voltage of the capacitor 152 is zero, then thedependent current charges capacitor 152, to a dependent voltage PV.Finally, the comparator 154 receives the second reference voltage VR2and the dependent voltage PV thus generating the third pulse signal P3.When the dependent voltage PV is equal to the second reference voltageVR2, the third pulse signal P3 will change from negative to positive,then the controller 142 changes the second pulse signal P2 from positiveto negative, thus the second pulse signal P2 remains in the negativeuntil the end of the preset period T_(min), hence when the positivepulse signal of the clock signal clk occurs, the second pulse signal P2changes from negative to positive. The second pulse signal P2 istransmitted from the secondary side to the driver 130 at the primaryside through the coupling element 136 so that driver 130 stopsgenerating the first pulse signal P1. Finally, the driver 130 amplifiesthe second pulse signal P2, generates a first digital signal D1, andtransmits it to the first electronic switch 132, which then changes itsON/OFF state accordingly to control the input voltage V_(IN) received bythe transformer 124, thereby regulating the output voltage V_(O) andoutput current I_(O). Specifically, when the first digital signal D1 isa low level signal, the first electronic switch 132 is in the OFF state,hence transformer 124 increases the output voltage V_(O) and outputcurrent I_(O). When the first digital signal D1 is a high level signal,the first electronic switch 132 is turned on, and transformer 124reduces the output voltage V_(O) and output current I_(O).

With reference to FIG. 2 and formula (1), when the load 31 is a lightload, I_(O) will decrease, so the switching frequency will decreaseaccordingly. When the switching frequency reaches 20-20 k hertz (Hz), itcan be easily detected by human ear. To avoid this problem, wheneverload 31 is a light load, t_(on) needs to be decreased. This is describedbelow in the ninth embodiment of the present invention shown in FIGS.21-23.

As shown in FIG. 21, the constant on-time isolated converter isconnected to an input terminal 156 and receives an input voltage V_(IN),which comprises a transformer 158 with its primary side connected to theinput terminal 156, and its secondary side connected to an outputcapacitor 160, which is connected to a low potential VSS, and to a load162 with an output signal, including an output voltage V_(O) and anoutput current I_(O), crossing the load 162. The secondary side of thetransformer 158 and load 162 are connected to a processor 164 that ispreset with a time period T_(min), a first reference voltage VR1, a lowthreshold frequency and a high threshold frequency. Processor 164receives the output signal from the load 162, and sequentially capturesthe first detection voltage DE1 and second detection voltage DE2 fromthe output signal. When the first detection voltage DE1 is less than thefirst reference voltage VR1, the processor 164 generates a first pulsesignal P1 and a synchronized first clock signal clk1 of the samefrequency within the preset period T_(min). Then, when the seconddetection voltage DE2 is less than the first reference voltage VR1,based on at least one frequency F of the first clock signal clk1, thelow threshold frequency and the high threshold frequency, processor 164generates a second pulse signal P2 and a synchronized second clocksignal clk2 of the same frequency within the preset period T_(min). Thesecond pulse signal P2 is of at least one cycle, where the voltage ineach of the first half cycle of the second pulse signal P2 is at a highvoltage level and the voltage in each of the second half cycle is at alow voltage level. Processor 164 is connected to at least one couplingelement 166, which can be capacitors, transformers, piezoelectricelement or optical coupling element. Coupling element 166 is connectedto both the primary side and secondary side of the transformer 158 andtransmits the first pulse signal P1 and the second pulse signal P2sequentially from secondary side to the primary side. The primary sideof the transformer 158 and coupling element 166 is connected to a driver168, which sequentially receives the first pulse signal P1 and thesecond pulse signal P2, amplifies them, then respectively generates thefirst digital signal D1 and the second digital signal D2. The primaryside of the transformer 158 and the driver 168 is connected to a firstelectronic switch 170, such as N-channel MOSFET or a bipolar junctiontransistor. The first electronic switch 170 sequentially receives thefirst signal digital D1 and the second digital signal D2, andaccordingly changes its ON/OFF state to control the input voltage V_(IN)received from the input terminal 156, thereby regulating the outputsignal. The duration for the ON/OFF state of the first electronic switch170 is determined between the moment the first pulse signal P1 changesfrom negative to positive and the moment the first pulse signal P1changes from positive to negative, or between the moment the secondpulse signal P2 changes from negative to positive and the moment thesecond pulse signal P2 changes from positive to negative. For example,when the first pulse signal P1 is the clock signal and changes fromnegative to positive, the first electronic switch 170 is turned on andremains on until the clock signal goes from positive to negative, i.e.,when its ON state is ended, and thus the first electronic switch 170 isturned off and remains off until the clock signal changes from negativeto positive, i.e., when its OFF state is ended, and thus the firstelectronic switch 170 is turned on again. Similarly, when the secondpulse signal P2 is a clock signal and changes from negative to positive,the first electronic switch 170 is turned on and remains on until theclock signal changes from positive to negative, i.e., the ON state ofthe first electronic switch 170 is ended and thus the first electronicswitch 170 is turned off. The first electronic switch 170 remains offuntil the clock signal changes from negative to positive again, i.e.,when the OFF state of the first electronic switch 170 is ended and thusthe first electronic switch 170 is turned on again.

When the first electronic switch 170 is operating in the discontinuousmode, its switching frequency is represented by formula (3):

$\begin{matrix}{{{ii}.\mspace{14mu} f} = \frac{2 \times I_{o} \times L \times V_{o}}{V_{IN}^{2} \times t_{on}^{2}}} & (3)\end{matrix}$

Where V_(IN) is the input voltage, V_(O) is the output voltage, I_(O) isthe output current, L is the inductance of the transformer 158, t_(on)is the time for the ON state of the first electronic switch 170. Toavoid the switching frequency f from falling into the human audible zoneand creating noise problem, if there is only one frequency F that islower than the low threshold frequency, i.e., the first electronicswitch 170 receives the first digital signal D1 and is turned on, thedesign of the isolated converter in FIG. 21 allows the on-time t_(on) ofthe first electronic switch 170 to be longer when it is controlled bythe first digital signal D1 than when it is controlled by the seconddigital signal D2 to turned on. On the other hand, if F is higher thanthe high threshold frequency, the on-time t_(on) of the first electronicswitch 170 controlled by the first digital signal D1 is shorter than theon-time of the first electronic switch 170 when it is controlled by thesecond digital signal D2. As such, if the first electronic switch 170receives the first digital signal D1 and the switching frequency fallsinto the audible zone, when it receives the second digital signal D2 theswitching frequency will be outside the audible zone, thus the noiseproblem is solved.

When there is a plurality of frequencies F, the processor 164 hasmultiple features including a low threshold value, a high thresholdvalue, an initial value corresponding to the first pulse signal P1 and acounting condition. The counting condition is that when a frequency F isbelow the lower threshold frequency, the initial value increases by 1,and when a frequency F is higher than the high threshold frequency, theinitial value decreases by 1. Processor 164 uses either the lowthreshold frequency or the high threshold frequency and the countingcondition to evaluate each of frequency F sequentially to obtain a totalvalue. In addition, a total value that is greater than the highthreshold value is rounded down to the high threshold value, and a totalvalue that is less than the low threshold value is rounded up to the lowthreshold value. Furthermore, the initial value, the low thresholdvalue, the high threshold value and the total value are all greater thanor equal to zero, represented by at least one or more binary bits. Forexample, if the low threshold value is 00, the high threshold value is11, the initial value is 00, and there are 5 frequencies F eachrespectively is: lower than low threshold frequency, higher than highthreshold frequency, lower than low threshold frequency, higher thanhigh threshold frequency, lower than low threshold frequency, whichresults in a total value of 01. Using the same value for the lowthreshold value, the high threshold value, the initial value, but 5different frequencies F, all of which are higher than the high thresholdfrequency, thus resulting in a total value smaller than the lowthreshold value, therefore the total value is 00. Again, using the sameparameters but a different set of 5 frequencies F each of which is lowerthan the low threshold frequency, the total value is greater than thehigh threshold value, so the total value is 11.

The processor 164 generates a second pulse signal P2 and the secondclock signal clk2 according to the total value. Similarly, to reducenoise when the switching frequency is in the audible zone, when thetotal value is larger than the initial value, the on-time for the firstelectronic switch 170 controlled by the first digital signal D1 islonger than that controlled by the second digital signal D2. When thetotal value is less than the initial value, the on-time for the firstelectronic switch 170 controlled by the first digital signal D1 isshorter than that controlled by the second digital signal D2. When thetotal value is equal to the initial value, the on-time for the firstelectronic switch 170 controlled by the first digital signal D1 equalsto the on-time for the first electronic switch 170 controlled by thesecond digital signal D2. In addition, the greater the differencebetween the total value and the initial value, the greater thedifference between the on-time of the first electronic switch 170controlled by the first digital signal D1 and that controlled by thesecond digital signal D2.

The driver 168 is connected to the input terminal 156 to receive aninput voltage V_(IN), thereby generating a third pulse signal P3 to thefirst electronic switch 170, which changes the ON/OFF state of the firstelectronic switch 170 accordingly to control the transformer 158receiving the input voltage V_(IN) from the input terminal 156, thusproducing an output signal to the load 162 and further controlling thegeneration of the first pulse signal P1 and the second pulse signal P2by the processor 164 via transformer 158. When the driver 168 receivesthe first pulse signal P1, it stops producing the third pulse signal P3.

The processor 164 comprises an electrical signal extractor 172, acontroller 174 and an on-time regulator 176. The electrical signalextractor 172 is connected to a low potential VSS, the secondary side ofthe transformer 158 and load 162, and receives the output signal tocapture the first detection voltage DE1 and second detection voltage DE2sequentially. The controller 174 is connected to coupling elements 166,the secondary side of the transformer 158 and the electrical signalextractor 172. The controller 174 is preset with a predetermined periodT_(min), the first reference voltage VR1, the counting condition, thelow threshold frequency, the high threshold frequency, the initialvalue, the low threshold value and the high threshold value, andreceives the first detection voltage DE1 and the second detectionvoltage DE2 sequentially. When the first detection voltage DE1 is lessthan the first reference voltage VR1, the controller 174 generates thefirst pulse signal P1 and the first clock signal clk1 within the presetperiod T_(min), and uses either the low threshold frequency or the highthreshold frequency and the counting condition to evaluate each of thefrequency F chronologically in order to obtain the total value. Then,when the second detection voltage DE2 is less than the first referencevoltage VR1, the controller 174, based on the total value, generates thesecond pulse signal P2 and the second clock signal clk2 within thepreset period T_(min). The second clock signal clk2 is a positive pulsesignal when the second pulse signal P2 changes from negative topositive; otherwise it is a low value signal. The on-time regulator 176is connected to controller 174 to receive the total value and the secondclock signal clk2 and then generates a fourth pulse signal P4 based onthe total value and the second clock signal clk2, so that when thefourth pulse signal P4 changes from negative to positive, the secondpulse signal P2 changes from positive to negative and thus remainsnegative until the end of the preset period T_(min). The secondelectronic switch 178, such as N-channel MOSFET, is connected betweenthe secondary side of the transformer 158 and the load 162 and is alsoconnected to the low potential VSS and controller 174. When thecontroller 174 generates the first pulse signal P1 or the second pulsesignal P2, a third digital signal D3 is also generated to the secondelectronic switch 178 to change the ON/OFF state of the first electronicswitch 170 and the second electronic switch 178 so that they are inopposite ON/OFF states or both are in OFF state.

As shown in FIG. 22, the on-time regulator 176 comprises a first currentsource 180, at least one current generator 182, a third electronicswitch 184, a capacitor 186 and a comparator 188. The first currentsource 180 generates a first current, and the current generator 182 isconnected to the controller 174 to receive the bits B1, B2 for the totalvalue, and thus accordingly generates at least one second current orzero current. Third electronic switch 184 is connected to controller174, the first current source 180 and the current generator 182. Thethird electronic switch 184 receives the first clock signal clk1 and isinstantly turned on when the first clock signal clk1 is a positive pulsesignal; otherwise the third electronic switch 184 is turned off in therest of time. Alternatively, the third electronic switch 184 receivesthe second clock signal clk2 and is instantly turned on when the secondclock signal clk2 is a positive pulse signal; otherwise the thirdelectronic switch 184 is turned off in the rest of time. Capacitor 186and the third electronic switch 184 are connected in parallel and areconnected to the first current source 180 and the current generator 182.According to the ON/OFF state of the third electronic switch 184,capacitor 186 receives the first current and either the second currentor zero-current and thus stores a dependent voltage. The positive inputterminal of the comparator 188 is connected to capacitor 186 to receivethe dependent voltage and the negative input terminal receives a secondreference voltage VR2, while the output terminal of the comparator 188is connected to the controller 174. The comparator 188 generates aninitial pulse signal PS or the fourth pulse signal P4 according to thedependent voltage stored in the capacitor 186 and the second referencevoltage VR2.

In an alternative embodiment, the on-time regulator 176 comprises aplurality of current generators 182, which after receiving the bits B1,B2 of the total value generate a plurality of second currentsrespectively. When the bit is 0, the corresponds current generator 182produces a zero current, while when the bit is 1, the correspondingcurrent generator 182 generates the second current with a magnitudecorresponding to a binary power of the bit in the plural binary bits ofthe total value. In FIG. 22, the on-time regulator 176 comprises twocurrent generators 182 generating two second currents respectively,where one current generator 182 receives a lower bit B1 of the totalvalue, and the other current generator 182 receives the higher bit B2 ofthe total value. Since the first current is continuously generated, thesecond current is larger with higher total value. In other words, whenthe total value is higher, the time taken for the dependent voltagestored in the capacitor 186 to reach the second reference voltage VR2 isshorter, leading to a shorter duration for the second pulse signal P2with high voltage level, hence the on-time for the first electronicswitch 170 after receiving the second digital signal D2 is shorter,avoiding the audible zone and reducing the noise component.

As shown in FIG. 22, each current generator 182 comprises a fourthelectronic switch 190 and a second current source 192. The fourthelectronic switch 190 is connected to controller 174, the thirdelectronic switch 184 and the capacitor 186, to receive one bit of thetotal value and accordingly changes its ON/OFF state. A second currentsource 192 connected to the fourth electronic switch 190 and accordingto the ON/OFF state of the electronic switch 190 generates a secondcurrent or zero current.

The startup mode operation of the ninth embodiment is described asfollows. First, the driver 168 receives the input voltage V_(IN) fromthe input terminal 156, thus generating the third pulse signal P3 to thefirst electronic switch 170, which changes its ON/OFF state accordinglyto control the input voltage V_(IN) transmitted to the transformer 158,producing the output signal on load 162 through the second electronicswitch 178 and the electronic signal extractor 172. Meanwhile, thetransformer 158 also provides energy to controller 174. Specifically,when the third pulse signal P3 is a high voltage level signal, the firstelectronic switch 170 is turned on, thus the transformer 158 storesenergy, while the output capacitor 160 supplies energy to produce theoutput signal and provide energy to the controller 174. When the thirdpulse signal P3 is a low voltage level signal, the first electronicswitch 170 is turned off, thus the transformer 158 releases energy togenerate the output signal and provides energy to the controller 174,while energy is stored in the output capacitor 160.

Then, the electronic signal extractor 172 receives the output signal,captures and sends the corresponding first detection voltage DE1 to thecontroller 174. The controller 174 receives the first detection voltageDE1 using energy supplied by transformer 158 and output capacitor 160,and when the first detection voltage DE1 is less than the firstreference voltage VR1, controller 174 generates a first pulse signal P1and the corresponding first clock signal clk1 within the preset periodT_(min), and transmits the signal clk1 to the on-time regulator 176. Thecontroller 174 also generates a third digital signal D3 according to thefirst pulse signal P1, transmits it to the second electronic switch 178to change the ON/OFF state of the second electronic switch 178. Forexample, when two bits BS1, BS2 binary number of the initial value is00, the low threshold value is 00, the high threshold value is 11, thecontroller 174 transmits the two bits BS1, BS2 of the initial value atthe same time to the on-time regulator 176.

Inside the on-time regulator 176, each of the two fourth electronicswitches 190 receives the bit BS for BS2 respectively of the initialvalue of 0, hence they are in the OFF state. At the starting, the firstclock signal clk1 is a positive pulse signal, while it is a low levelsignal in the remaining time, the first pulse signal P1 also starts tochange from negative to positive, thus the third electronic switch 184is turned on momentary, causing the voltage across capacitor 186 to bezero, and then the comparator 188 compares the voltage across capacitor186 with the second reference voltage VR2 to produce an initial pulsesignal PS at a low level voltage. Next, the first current produced bythe first current source 180 charges the capacitor 186, when the voltageacross the capacitor 186 reaches the second reference voltage VR2, theinitial pulse signal PS changes from negative to positive, causing thefirst pulse wave signals P1 to change from positive to negative andremaining in negative at least until the end of the preset periodT_(min), when the second clock signal clk2 appears. Within this presetperiod T_(min), controller 174 captures five frequencies F of the firstclock signal clk1 chronologically. Using either the low thresholdfrequency or the high thresholds frequency and the counting condition,controller 174 evaluates each frequency F sequentially, and finds thatall five frequencies F are below the low threshold frequency, as suchthe two bits B1, B2 of the total value are 11. This five frequencies Fcan be measured from a single cycle or from different cycles of thefirst clock signal clk1.

The first pulse signal P1 is then transmitted from the secondary sidethrough the coupling element 166 to the driver 168 at the primary side,which stops generating the third pulse signal P3 upon receiving thefirst pulse signal P1. Finally, the driver 168 amplifies the first pulsesignal P1 generating the first digital signal D1, which is transmittedto the first electronic switch 170, thus the ON/OFF state of the firstelectronic switch 170 is changed accordingly to control the inputvoltage V_(IN) transmitted to the transformer 158, thereby regulatingthe output signal. Specifically, when the first digital signal D1 is alow voltage level signal, the first electronic switch 170 is turned off,causing transformer 158 to increase the output signal; when the firstdigital signal D1 is a high voltage level signal, the first electronicswitch 170 is turned on, and transformer 158 reduces the output signal.

After that, the electronic signal extractor 172 receives the outputsignal again and retrieves and transmits the corresponding seconddetection voltage DE2 to the controller 174. The controller 174 receivesthe second detection voltage DE2 using the energy supplied bytransformer 158 and the output capacitor 160, and when the seconddetection voltage DE2 is less than the first reference voltage VR1, thecontroller 174 generates the second pulse signal P2 and thecorresponding second clock signal clk2 within the preset period T_(min),and transmit the signal clk2 to the on-time regulator 176. Thecontroller 174 also generates a third digital signal D3 according to thesecond pulse signal P2, transfers it to the second electronic switch 178to change the ON/OFF state of the second electronic switch 178. At thesame time, controller 174 sends the two bits B1, B2 of the total valueto the on-time regulator 176.

Inside the on-time regulator 176, since each the two bits B1, B2 of thetotal value separately received by the two fourth electronic switches190 is 1, both the fourth electronic switches 190 are turned on. Thesecond clock signal clk2 is a positive pulse signal, while it is a lowvoltage level signal in the remaining time, hence it goes from negativeto positive at the starting, causing the third electronic switch 184 tomomentary turn on, so the voltage across capacitor 186 is zero, thus thecomparator 188 compares the voltage across capacitor 186 with the secondreference voltage VR2 to produce a fourth pulse signal P4 at a low levelvoltage. Next, the first current generated by the first current source180 and the second current generated by the second current source 192charges the capacitor 186. When the voltage across capacitor 186 reachesthe second reference voltage VR2 again, the fourth pulse signal P4changes from negative to positive, causing the second pulse signal P2 togo from positive to negative, and remains negative at least until theend of the preset period T_(min). Compared to when it only receives thefirst current, capacitor 186 is able to reach the second referencevoltage VR2 faster, so the instance for the second pulse signal P2 tochange from positive to negative is earlier compared to that when thefirst pulse signal P1 goes from positive to negative, which means theduration for the second pulse signal at the high voltage level voltageis shorter than that of the first pulse signal P1.

Through the coupling element 166, the second pulse signal P2 istransmitted from the secondary side to the driver 168 at the primaryside, which amplifies the second pulse signal P2, generates the seconddigital signal D2, and transmits the second digital signal D2 to thefirst electronic switch 170, which changes the ON/OFF state of the firstelectronic switch 170 accordingly to control the input voltage V_(IN)transmitted to transformer 158 from the input terminal 156, therebyregulating the output signal. Specifically, when the second digitalsignal D2 is a low voltage signal, the first electronic switch 170 isturned off, and transformer 158 increases the output signal. When thesecond digital signal D2 is a high level signal, the first electronicswitch 170 is turned on, and transformer 158 reduces the output signal.Since duration of the second pulse signal P2 at the high level isshorter than that of the first pulse signal P1, the duration for thesecond digital signal D2 at the high voltage level will be shorter thanthat of the first digital signal D1, resulting in a smaller t_(on),hence preventing the switching frequency f from entering the audiblezone and thereby reducing the noise component.

In the above-described embodiment, the controller 174 uses energysupplied by the transformer 158 to start its operation, which requiresthe driver 168 to receive an input voltage V_(IN) to generate a thirdpulse signal P3 that switches the first electronic switch 170 and alsodrives the transformer 158 to provide energy to the secondary side sothat the controller 174 can start to operate. However if an externalcircuit is directly connected and supplies energy to the controller 174,the driver 168 is no longer required to produce the third pulse signalP3 to drive the first electronic switch 170 and the transformer 158. Theisolated converter can directly receive the output signal from theelectronic signal extractor 172 to begin operation.

Referring to FIG. 21, FIG. 23 and FIG. 24, as shown in the analogwaveform diagram of FIG. 24, the positive pulse waveform DOWN representsthe total value minus 1, the positive pulse waveform UP represents thetotal value plus 1, the high level waveform of LD represents the load162 being lightly loaded, high level waveform of B1 or B2 represents avalue of 1, low level waveform of B1 or B2 represent a value of 0. Asshown in FIG. 21, when the load 162 is a light loaded, I_(O) decreases.When the frequency F is below the low threshold frequency, positivepulse waveform appears in UP, then the bits B1 and B2 of the total valuewill change correspondingly between 1 and 0, forming high levelwaveform, avoiding the audio zone. When the frequency F is higher thanthe high threshold frequency, positive pulse waveform appears in DOWN,then the bits B1 and B2 of the total value will change correspondinglybetween 1 and 0, forming a low level waveform.

In summary, the present invention uses the information at the secondaryside to determine the duration of the ON/OFF state of the electronicswitch in primary side of the transformer, thereby regulating the outputsignal, while achieving a variety of purposes.

Those of ordinary skill in the art may recognize that modifications ofthe embodiments disclosed herein are possible. Other modifications mayoccur to those of ordinary skill in this art, and all such modificationsare deemed to fall within the purview of the present invention, asdefined by the claims.

1. A constant on-time (COT) isolated converter connected to an inputterminal for receiving an input voltage, the COT isolated convertercomprising: a transformer comprising a primary side; and a secondaryside; the primary side being connected to the input terminal and thesecondary side being connected to a load; a processor connected to thesecondary side of the transformer and the load; the processor receivingan output voltage or an output current applied onto the load to generatea control signal; a driver connected to the primary side of thetransformer; the driver receiving and amplifying the control signal togenerate a first digital signal; and a first electronic switch connectedto the primary side of the transformer and the driver; wherein the firstelectronic switch receives the first digital signal, and accordinglychanges an ON/OFF state of the first electronic switch to regulate thetransformer receiving the input voltage from the input terminal, thusgenerating the output voltage and the output current; wherein a durationfor the ON/OFF state of the first electronic switch is determined by afirst instance the control signal changes from negative to positive anda second instance the control signal changes from positive to negative.2. The COT isolated converter of claim 1, wherein in a discontinuousmode, a switching frequency, f, of the first electronic switch isrepresented by${f = \frac{2 \times I_{o} \times L \times V_{o}}{V_{IN}^{2} \times t_{on}^{2}}},$wherein V_(IN) is the input voltage, V_(O) is the output voltage, I_(O)is the output current, L is an inductance of the transformer, and t_(on)is a duration for an ON state of the first electronic switch.
 3. The COTisolated converter of claim 1 further comprising at least one couplingelement connected between the processor on the secondary side of thetransformer and the driver on the primary side of the transformer;wherein the at least one coupling element transmits the control signalfrom the secondary side to the primary side of the transformer.
 4. TheCOT isolated converter of claim 1, wherein the driver is connected tothe input terminal to receive the input voltage, thereby generating afirst pulse signal transmitted to the first electronic switch; whereinthe first electronic switch changes the ON/OFF state of the firstelectronic switch according to the first pulse signal to control thetransformer receiving the input voltage from the input terminal thusproducing the output voltage and the output current applied onto theload; and wherein the processor receives a start-up voltage provided bythe transformer and generates the control signal transmitted to thedriver, whereby the driver stops generating the first pulse signal uponreceiving the control signal.
 5. The COT isolated converter of claim 4,wherein the processor is connected to an external circuit to provide thestart-up voltage to the processor.
 6. The COT isolated converter ofclaim 4 further comprising a diode comprising an anode connected to thesecondary side of the transformer; and a cathode connected to the load;wherein the transformer receives the input voltage and regulates theoutput voltage and the output current through the diode.
 7. The COTisolated converter of claim 4, wherein the processor comprises: anelectrical signal extractor connected to the secondary side of thetransformer and the load; the electrical signal extractor capturing afeedback voltage of the output voltage or a detection voltagecorresponding to the output current; and a controller connected to acoupling element, the secondary side of the transformer and theelectrical signal extractor; the controller receiving the start-upvoltage, the feedback voltage or the detection voltage, to generate acontrol voltage signal accordingly.
 8. The COT isolated converter ofclaim 7 further comprising a second electronic switch connected betweenthe secondary side of the transformer and the load, and furtherconnected to the controller; wherein, during a period while thecontroller generating the control signal, the controller based on thefeedback voltage or the detection voltage, and the start-up voltage,generates a second digital signal transmitted to the second electronicswitch to control an ON/OFF state of the second electronic switch suchthat the first electronic switch is in an ON state and the secondelectronic switch is in an OFF state; the first electronic switch is inan OFF state and the second electronic switch is in an ON state; or thefirst electronic switch is in the OFF state and the second electronicswitch is in the OFF state.
 9. The COT isolated converter of claim 8,wherein the second electronic switch is an N-channel metal oxidesemiconductor field effect transistor (MOSFET).
 10. The COT isolatedconverter of claim 7, wherein the controller is provided with a presetreference voltage; wherein, when the feedback voltage is less than thepreset reference voltage, the control signal is a second pulse signal ofat least one cycle, each cycle of the at least one cycle of the secondpulse signal provides a high level voltage in a first half cycle and alow level voltage in a second half cycle; and wherein, when the feedbackvoltage is greater than the preset reference voltage, the control signalprovides the low level voltage.
 11. The COT isolated converter of claim7, wherein the controller is provided with a preset reference voltage;wherein, when the detection voltage is less than the preset referencevoltage, the control signal is a second pulse signal of at least onecycle, each cycle of the at least one cycle of the second pulse signalprovides a high level voltage in a first half cycle and a low levelvoltage in a second half cycle; and wherein, when the detection voltageis greater than the reference voltage, the control signal provides thelow level voltage.
 12. The COT isolated converter of claim 7, whereinthe electrical signal extractor is a voltage divider capturing adivision of the output voltage to provide the feedback voltage.
 13. TheCOT isolated converter of claim 7, wherein the electrical signalextractor is a resistor; wherein the output current flows through theresistor producing the detection voltage on the resistor.
 14. The COTisolated converter of claim 7, wherein the controller, the couplingelement and the driver are integrated in a packaged structure.
 15. TheCOT isolated converter of claim 14, wherein the coupling element is acapacitor; wherein the packaged structure comprises a firstsemiconductor chip; a dielectric layer; and a second semiconductor chip;wherein the controller is formed on the first semiconductor chip, thedriver is formed on the second semiconductor chip, and the capacitor isformed by the first semiconductor chip, the dielectric layer and thesecond semiconductor chip.
 16. The COT isolated converter of claim 1,wherein the first electronic switch is an N-channel metal oxidesemiconductor field effect transistor or a bipolar junction transistor.